ArticleName |
Production of marketable products
by processing tin-copper ore tailings |
ArticleAuthorData |
SRC Hydrometallurgy (LLC), Saint Petersburg, Russia:
A. Yu. Lapin, Principal Researcher, Candidate of Technical Sciences, e-mail: lapin-a@gidrometall.ru T. Yu. Kositskaya, Senior Researcher, Candidate of Technical Sciences, e-mail: kositskaya-t@gidrometall.ru Ya. M. Shneerson, R&D Director, Doctor of Technical Sciences, Professor, e-mail: shneerson-y@gidrometall.ru
Geoprominvest LLC, Khabarovsk, Russia: V. I. Bogdanov, Deputy Director, e-mail: tatjna.1950@mail.ru |
Abstract |
The problem of processing raw materials from man-made deposits, which are basically ore tailings, is currently of relevance. Thus, for instance, man-made Sn – Cu raw materials can be processed into marketable products. This paper describes the results of a study that looked at the production of commercial Sn and Cu concentrates using well-known processing techniques. Two different processing schemes were developed for the primary Cu and Sn concentrates, which are the result of the beneficiation stage. The problem of removing As, the concentration of which in the primary raw material is higher than that of the other non-ferrous metals, was also resolved for both processing schemes. The process of producing commercial copper concentrate containing 60–70% Cu and less than 0.3% As involves the following stages: pressure oxidation of the sulfide raw material; purification of the solution; and recovery of metal into a high-grade concentrate. A few process options were considered for the tin ore. The final proposal is to use the following production scheme: the Sn middlings are first to be treated in acid medium (autoclaving) and then – in the alkaline medium at normal atmospheric pressure. This process uses minimum alkali and produces almost no sodium salts that are not easily disposable of. Besides, it allows to process high-arsenic tailings while producing commercial Sn concentrates containing 45–47% Sn and less than 0.3% As. All the operations of these two processes were tested, and it helped define and optimize the key parameters and indicators of the Cu and Sn production lines. |
References |
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